JP6806904B1 - How to Make Solar Cells, Boarding Modules, and Solar Cells for Boarding Modules - Google Patents

Abstract

The present invention relates to a solar cell for a boarding module, a boarding module, and a method for manufacturing a solar cell. The solar cell includes a front surface of the solar cell and a back surface of the solar cell, a plurality of front bus bars are arranged on the front surface of the solar cell, and a plurality of rear bus bars are arranged on the back surface of the solar cell. The solar cell comprises a plurality of sections, each section comprising one front busbar and one rear busbar located at its edge, and the front busbar of at least one section of the solar cell. It has an extension at one end or both ends, the extension extending along the other edge that intersects the edge in the at least one section. The boarding module is created by strips of solar cells separated from the solar cells.

Description

The present invention relates to a solar cell for a boarding module, a boarding module, and a method of manufacturing a solar cell for a boarding module.

As the rate of consumption of ordinary fossil energy such as coal, oil, and natural gas accelerates in Global, the living environment is deteriorating, and greenhouse gas emissions in particular lead to severe global climate change every day. , Sustainable development of human society is a serious threat. Countries around the world have developed their own energy development strategies to address the finiteness of ordinary fossil energy and the environmental problems of development and utilization. Solar energy has become one of the most important renewable energies due to its characteristics of certainty, safety, generality, long-term use time, environmental protection, and resource sufficiency, and will be important for future global power supply. It can be expected to become a pillar.

Against the background of the powerful propulsion and use of clean energy called solar energy, the plate-roofing module technology can significantly improve the module power, and the plate-roofing module manufacturing process has constant requirements for solar battery pattern design. In a normal board-roofed battery design, a strip of split solar cells is used to create a board-roofing module. Due to the non-uniform flow path designed for the busbar of the solar battery, the current collection path is long and the plate-roofed module can be manufactured to make the electroluminescence (EL) image darker than the middle. Affects the power output of the final module.

In particular, at present, single crystal silicon wafers for making plate-roofed modules have arc chamfers and do not have a sufficient battery-conductive adhesive-battery-like connection at the corresponding position of the plate-roofed battery string. The strip busbar at the edge of the solar cell has a shorter effective width than the middle, and when a boarding module is made using strips with chamfers in this way, the current collection path is long and the resistance is high at the chamfered part. The EL imaging in the area is darker than in the middle, affecting the power output of the module.

It is an object of the present invention to provide a solar cell for a boarding module that can overcome defects in the prior art.

The object is realized by a solar cell for a board-roofing module according to the present invention, the solar cell includes a front surface of the solar cell and a back surface of the solar cell, and a plurality of front bus bars are arranged on the front surface of the solar cell. , A plurality of rear bus bars are arranged on the back surface of the solar cell, and the solar cell includes a plurality of sections, each section having one front bus bar and one rear bus bar located at the edge thereof. The front busbar and / or rear busbar of at least one section of the solar cell comprises an extension at one end or both ends, the extension of which intersects the edge of the at least one section. Extend along.

The present invention has improved the power of the module by extending the front busbar and improving the current collection capability of the busbar.

According to one preferred embodiment of the present invention, the solar cell comprises chamfering, and an extension of the front and / or rear busbar in the chamfering section comprising at least one chamfering of the solar cell is the chamfering section. Extends along the other edge of the chamfered section that intersects the edge of the section in which the front and / or back busbar of the busbar is located. For example, when the front busbar and / or the back busbar extends along one long side of the chamfered section without chamfering, the front busbar and / or the back busbar is the other edge perpendicular to the long edge of the chamfered section. That is, after reaching its short edge, the front busbar and / or the back busbar subsequently extends along the short edge. Here, by extending the bus bar of the chamfered portion and improving the current collecting ability of the bus bar in the chamfered portion, the EL imaging of the chamfered plate-roofing module was improved and the power of the chamfered module was improved.

The extension preferably extends along a portion or the entire area of the other edge of the chamfered section.

In addition, the extension extends along the entire area of the other edge of the chamfered section, and subsequently along a portion or the entire area of another edge adjacent to the other edge of the chamfered section. It is preferable to extend. For example, when the front busbar extends along one long side of the chamfered section without chamfering, the front busbar reaches the other edge perpendicular to the long edge of the chamfered section, i.e. its short edge, and then said. The front busbar subsequently extends along the entire area of the short edge, and subsequently along another edge adjacent to the short edge of the chamfered section, i.e. a part or entire area at the edge of the chamfer.

According to one preferred embodiment of the present invention, the extension portion is straight and the width does not gradually change, or is straight and the width gradually changes.

According to one preferred embodiment of the present invention, the plurality of front busbars are arranged in front of the solar cell at equal intervals.

According to one preferred embodiment of the present invention, the plurality of front busbars are arranged in front of the solar cell at uneven intervals.

It is preferred that the plurality of frontal busbars include two adjacent frontal busbars so that the two adjacent frontal busbars are not close to the edge of the solar cell with respect to the other frontal busbars.

The plurality of front bus bars include two pairs of front bus bars, two front bus bars of each of the two pairs of front bus bars are adjacent to each other, and the two adjacent front bus bars are each one edge of the solar cell. It is preferable to be close to.

It is preferred that the plurality of front busbars include two adjacent front busbars, the two adjacent front busbars being close to the edge of the solar cell.

The plurality of front bus bars include two pairs of front bus bars, two front bus bars of each of the two pairs of front bus bars are adjacent to each other, and one pair of front bus bars of the two pairs of front bus bars is the solar cell. It is preferable that the two pairs of front busbars are close to the edge and the other pair of front busbars are not close to the edge of the solar cell.

According to one preferred embodiment of the invention, after the solar cell is split into strips of a plurality of solar cells, the front busbar is on one long edge of each solar cell strip and a short edge adjacent thereto. The arrangement of the plurality of rear busbars may correspond to the arrangement of the plurality of front busbars so that the rear busbars are closer to the long edge on the other side.

According to another aspect of the present invention, there is provided a boarding module made of strips of solar cells separated from the solar cells according to any one of the above embodiments.

According to another aspect of the present invention, a method of manufacturing a solar cell for a boarding module is provided, in which a plurality of busbars are arranged on the front and back surfaces of the solar cell, and the plurality of busbars are provided. The solar cell is divided into a plurality of sections, each of which comprises one front bus bar and one rear bus bar located at the edge thereof, and the bus bar of at least one section of the solar cell is at one end or both ends. It comprises an extension, wherein the extension extends along another edge that intersects the edge in the at least one section.

According to one preferred embodiment of the present invention, in the method of manufacturing a solar cell for a boarding module of the present invention, the solar cell comprises chamfering and in a chamfering section comprising at least one chamfering of the solar cell. An extension of the busbar extends along the other edge that intersects the edge on which the busbar is located in the chamfered section.

In the method of manufacturing a solar cell for a boarding module of the present invention, it is preferable that the extension portion extends along a part or the whole area at another edge of the chamfered section. In addition, the extension extends along the entire area of the other edge of the chamfered section, and subsequently along a portion or the entire area of another edge adjacent to the other edge of the chamfered section. It is preferable to extend.

According to one preferred embodiment of the present invention, in the method of manufacturing a solar cell for a plate-roofing module of the present invention, the extension portion is a straight line and the width does not gradually change or is a straight line. The width may change gradually.

According to one preferred embodiment of the present invention, in the method of manufacturing a solar cell for a boarding module of the present invention, the plurality of busbars may be a plurality of front busbars. Instead, the plurality of busbars may be rear busbars.

According to one preferred embodiment of the present invention, in the method of manufacturing a solar cell for a boarding module of the present invention, the plurality of front busbars are arranged in front of the solar cell at even intervals. May be good.

According to one preferred embodiment of the present invention, in the method of manufacturing a solar cell for a plate-roofing module of the present invention, the plurality of front busbars are arranged in front of the solar cell at uneven intervals. You may be.

In the method of manufacturing a solar cell for a boarding module of the present invention, the plurality of front busbars include two adjacent front busbars, and the two adjacent front busbars are said to have the solar cell relative to another front busbar. It is preferable not to be close to the edge of the.

In the method of manufacturing a solar cell for a boarding module of the present invention, the plurality of front busbars include two pairs of front busbars, and each of the two front busbars of the two pairs of front busbars are adjacent to each other. It is preferred that the front busbars of each be close to one edge of the solar cell.

In the method of manufacturing a solar cell for a boarding module of the present invention, the plurality of front busbars include two adjacent front busbars, and the two adjacent front busbars may be close to the edge of the solar cell. preferable.

In the method of manufacturing a solar cell for a boarding module of the present invention, the plurality of front busbars include two pairs of front busbars, each of the two front busbars of the two pairs of front busbars adjacent to each other, and the two pairs. It is preferable that the pair of front busbars of the front busbar of the above is close to the edge of the solar cell, and the other pair of front busbars of the two pairs of front busbars are not close to the edge of the solar cell.

According to one preferred embodiment of the present invention, in the method of manufacturing a solar cell for a plate-roofing module of the present invention, the busbar of at least one section of the solar cell having an extension portion at one end or both ends is a front surface. It is a bus bar.

According to the present invention, by designing to extend the bus bar of the chamfered portion and improving the current collecting ability of the bus bar in the chamfered portion, the EL imaging of the chamfered plate-roofing module is improved and the power of the chamfered module is improved. ..

1 and 2 show the front surface of the solar cell and the back surface of the solar cell according to the prior art by the top view and the bottom view, respectively. 3 and 4 show the front surface of the solar cell and the back surface of the solar cell of one preferred embodiment according to the present invention by top view and bottom view, respectively. FIG. 5 is a locally enlarged view showing the chamfered area of the solar cell in FIGS. 3 and 4. 6 and 7 show the front side of the solar cell and the back side of the solar cell of another preferred embodiment of the solar cell according to the present invention by top and bottom views, respectively. FIG. 8 is a locally enlarged view showing the chamfered area of the solar cell in FIGS. 6 and 7. 9 and 10 show the front surface of the solar cell and the back surface of the solar cell of still one preferred embodiment according to the present invention by top view and bottom view, respectively. 11 and 12 show the front surface of the solar cell and the back surface of the solar cell of another preferred embodiment of the solar cell according to the present invention by top and bottom views, respectively. 13 and 14 show the front surface of the solar cell and the back surface of the solar cell of another preferred embodiment of the solar cell according to the present invention by top and bottom views, respectively. 15 and 16 show the front and back of the solar cell of another preferred embodiment of the solar cell according to the present invention, respectively, with top and bottom views. 17 and 18 show the front surface of the solar cell and the back surface of the solar cell of another preferred embodiment of the solar cell according to the present invention by top and bottom views, respectively. 19 and 20 show the front surface of the solar cell and the back surface of the solar cell of another preferred embodiment of the solar cell according to the present invention by top and bottom views, respectively. FIG. 21 is a flow chart showing a method of manufacturing a solar cell for a plate-roofing module according to the present invention.

Hereinafter, the contents of the present invention will be described with reference to the drawings. Further, those skilled in the art can understand that the present invention is not limited to this, and equivalent contents are also included in the scope of the present invention.

1 and 2 show the front surface of the solar cell and the back surface of the solar cell of the solar cell 100 according to the prior art by the top view and the bottom view, respectively. The solar cell 100 includes chamfers 131, 132, 133, and 134.

A plurality of front bus bars 101, 102, 103, 104, 105 are arranged on the front surface of the solar cell, and a plurality of rear bus bars 106, 107, 108, 109, 110 are arranged on the back surface of the solar cell. The plurality of rear bus bars 106 are such that after the solar cell 100 is divided into strips of solar cells, each strip of each solar cell has a front bus bar on one side and a rear bus bar on the other side. , 107, 108, 109, 110 correspond to the arrangement of the plurality of front bus bars 101, 102, 103, 104, 105.

As shown in FIGS. 1 and 2, the solar cell 100 can be divided into strips of five solar cells, and the strips of the first solar cell are the front bus bar 101 and the rear bus bar 106 in the order shown in FIGS. 1 and 2. The strip of the second solar cell has the front bus bar 102 and the rear bus bar 107, the strip of the third solar cell has the front bus bar 103 and the rear bus bar 108, and the strip of the fourth solar cell has the front bus bar 104. And the rear bus bar 109, and the strip of the fifth solar cell comprises the front bus bar 105 and the rear bus bar 110. In particular, the strips of solar cells with chamfers on the edges of the solar cells have a longer current collection path and resistance in the chamfered part when using it to create a boarding module because the effective width of the busbar is shorter than the middle. Is large and the EL imaging in the area is darker than in the middle, affecting the power output of the module.

The present invention improves the EL imaging of the boarding module by improving the prior design of FIGS. 1 and 2 to increase the current collecting capacity of the bus bar, particularly the current collecting capacity at the chamfered portion, and thus the boarding module. Improve power. 3 to 12 show a number of preferred embodiments of the solar cell according to the invention.

3 and 4 show the front surface of the solar cell and the back surface of the solar cell of the solar cell 200 of one preferred embodiment according to the present invention by top view and bottom view, respectively. The solar cell 200 shown in the figure consists of slices of square bars with four ridges chamfered, so when viewed from the front of the solar cell and the back of the solar cell, the solar cell is almost square with chamfers at the four corners. Is. That is, the solar cell 200 includes chamfers 221, 222, 223, and 224.

A plurality of parallel front bus bars 201, 202, 203, 204, 205 parallel to two edges in the solar cell are arranged on the front surface of the solar cell, and a solar cell is arranged on the back surface of the solar cell. A plurality of parallel rear busbars 206, 207, 208, 209, 210 parallel to the same two edges inside are arranged. The solar cell comprises a plurality of juxtaposed sections 231, 232, 233, 234, 235, each containing one front busbar and one rear busbar, respectively.

In this embodiment, the plurality of front bus bars 201, 202, 203, 204, 205 are arranged in front of the solar cell at uneven intervals. The plurality of front bus bars 201, 202, 203, 204, 205 include two adjacent front bus bars 202, 203, and the two adjacent front bus bars are on the edge of the solar cell with respect to the other front bus bars. Not close. In this embodiment, the two adjacent front busbars 202, 203 are located in the section closer to the center. However, the present invention is not limited to this, and in other embodiments, the plurality of front busbars may be evenly spaced in front of the solar cell, with the front busbar at the edge of the solar cell. May be close.

After the solar cell 200 is split into strips of solar cells in the section, each strip of solar cell has a front busbar on one long edge and a back busbar on the other long edge, and at least one. The arrangement of the plurality of rear busbars 206, 207, 208, 209, 210 is such that the plurality of rear busbars 206, 207, 208, 209, 210 are arranged such that the strips of one solar cell have front busbars on one long edge and short edges intersecting the front busbars 201. Corresponds to the arrangement of 202, 203, 204, 205. As shown in FIGS. 3 and 4, the solar cell 200 can be divided into five solar cell strips, with the first solar cell strip being the front busbar from left to right in the order shown in FIGS. 3 and 4. The strip of the second solar cell has the front bus bar 202 and the rear bus bar 207, the strip of the third solar cell has the front bus bar 203 and the rear bus bar 208, and the strip of the fourth solar cell has 201 and the rear bus bar 206. The strip comprises a front bus bar 204 and a rear bus bar 209, and the strip of the fifth solar cell comprises a front bus bar 205 and a rear bus bar 210. As described above, each of the strips of the first to fifth solar cells has a front bus bar on one long edge and a rear bus bar on the other long edge, and the first one. ~ At least one solar cell strip in the fifth solar cell strip has a front busbar on one long edge and a short edge that intersects it, in other words, the long edge has a busbar and the intersecting short edges It has an extension of the busbar.

Specifically, the two outermost solar cell strips in the first to fifth solar cell strips, that is, the first solar cell strip and the fifth solar cell strip, are chamfered. The strip of the first solar cell is also the chamfer section 231 on the left side, and the strip of the fifth solar cell is also the chamfer section 235 on the right side. The front busbar 201 in the left chamfered section 231 with chamfers extends along the long side on one side without chamfers and after reaching the short side intersecting the long side (the embodiment in the figure is vertical). The front bus bar 201 subsequently extends along the short side, i.e. includes an extension portion 211 of the bus bar. FIG. 5 is a locally enlarged view showing the chamfered 221 area of the solar cell, wherein the extension portion 211 of the bus bar 201 is more clearly observed by FIG. As shown in the figure, the extension portion 211 extends along the short edge 231-1 of the chamfered section 231. The extension portion 211 may extend all the way to chamfer 221 or may extend along a portion of the area of the short edge 231-1 and not extend to chamfer 221. The extension portion 211 may be a straight line and the width does not gradually change, that is, may have a constant width, or may be a straight line and the width may gradually change, that is, may have a changing width.

By designing an extension of the front busbar near the intersecting short sides or chamfers of the solar cell, it is possible to increase the current collection capacity of the solar battery and improve the power of the boarding module.

Similarly, the strip of the fifth solar cell, the front busbar 205 in the right chamfered section 235, extends along one long side without chamfers and intersects the long side (the embodiment in the figure is vertical). After reaching the short side (there is), the front bus bar 205 subsequently extends along the short side, i.e. comprises an extension of the bus bar. The extension extends along the short edge of the right chamfer section 235, and the extension may extend all the way to chamfer 222, or extend along only part of the short edge area to chamfer 222. It does not have to extend.

Of course, in the embodiments shown in the figure, the extension of the busbar is located on the lower short edge that intersects the long side of the strip of the solar cell, and one of ordinary skill in the art will eventually be on one short edge or above and below. It can be understood that the extension of the busbar may be installed on the two intersecting short edges.

6 and 7 show the front surface of the solar cell and the back surface of the solar cell of another preferred embodiment of the solar cell 300 according to the present invention by top and bottom views, respectively. The solar cell 300 shown in the figure consists of slices of square bars with four ridges chamfered, so when viewed from the front of the solar cell and the back of the solar cell, the solar cell is almost square with chamfers at the four corners. Is. That is, the solar cell 300 includes chamfers 321, 322, 323, and 324.

A plurality of parallel front bus bars 301, 302, 303, 304, 305 parallel to two edges in the solar cell are arranged on the front surface of the solar cell, and a solar cell is arranged on the back surface of the solar cell. A plurality of parallel rear busbars 306, 307, 308, 309, 310 parallel to the same two edges inside are arranged. The solar cell comprises a plurality of juxtaposed sections 331, 332, 333, 334, 335, each containing one front busbar and one rear busbar, respectively.

In the embodiments shown in FIGS. 6 and 7, the arrangement of the plurality of front busbars and the plurality of rear busbars is the same as that of the embodiments shown in FIGS. 3 and 4, so duplicate description will be omitted.

The front busbar 301 in the left chamfered section 331 with chamfers extends along the long side on one side without chamfers to the short side intersecting the long side, followed by the front busbar 301 along the short side. It is extended, that is, includes an extension portion 311 of the bus bar. FIG. 8 is a locally enlarged view showing the chamfered 321 area of the solar cell, wherein the extension portion 311 of the bus bar 301 is more clearly observed by FIG. In the present embodiment, the extension portion 311 extends along the entire area of the short edge 331-1 of the chamfered section 331 and subsequently extends along the chamfered edge 331-2 of the chamfered section 331. The extension portion 311 may extend along the entire area of the chamfered edge 331-2, or may extend along a portion of the area of the chamfered edge 331-2. The extension portion 311 may be a straight line and the width does not gradually change, that is, may have a constant width, or may be a straight line and the width may gradually change, that is, may have a changing width.

On the other side of the solar cell, the busbar 305 in the other chamfered section 335 with a chamfer may be provided with an extension extending along the short edge of the other chamfered section 335, the extension extending all the way up to the chamfer 322. It may extend or may extend along only part of the short edge area of the other chamfer section 335 and not extend to the chamfer 322. Further, the busbar 305 extension preferably extends along the entire short edge of the other chamfered section 335, followed by a portion or the entire area of the chamfered edge of the other chamfered section 335.

Of course, in the embodiments shown in the figure, the extension of the busbar is located on the lower short edge that intersects the long side of the strip of the solar cell, and one of ordinary skill in the art will eventually be on one short edge or above and below. It can be understood that the extension of the busbar may be installed on the two intersecting short edges.

9 and 10 show the front surface of the solar cell and the back surface of the solar cell of the solar cell 400 of one preferred embodiment according to the present invention by top view and bottom view, respectively. The solar cell 400 shown in the figure consists of a slice of a square bar with four ridges chamfered, so when viewed from the front of the solar cell and the back of the solar cell, the solar cell is almost square with chamfers at the four corners. Is. That is, the solar cell 400 includes chamfers 421, 422, 423, and 424.

A plurality of parallel front bus bars 401, 402, 403, 404, 405 parallel to two edges in the solar cell are arranged on the front surface of the solar cell, and a solar cell is arranged on the back surface of the solar cell. A plurality of parallel rear bus bars 406, 407, 408, 409, 410 parallel to the same two edges inside are arranged. The solar cell comprises a plurality of juxtaposed sections 431, 432, 433, 434, 435, each containing one front busbar and one rear busbar, respectively.

In this embodiment, the plurality of front bus bars 401, 402, 403, 404, 405 are arranged in front of the solar cell at uneven intervals. The plurality of front bus bars 401, 402, 403, 404, 405 include two pairs of front bus bars 401, 402 and 404, 405, and two front bus bars of each of the two pairs of front bus bars are adjacent to each other. A pair of front busbars 401, 402 and 404, 405 are each close to one edge of the solar cell. However, the present invention is not limited to this, and in other embodiments, the plurality of front busbars may be evenly spaced in front of the solar cell, with the front busbar at the edge of the solar cell. It does not have to be close.

After the solar cell 400 is split into strips of a plurality of solar cells in the section, each solar cell strip has a front busbar on one long edge and a back busbar on the other long edge. The arrangement of the plurality of rear bus bars 406, 407, 408, 409, 410 corresponds to the arrangement of the plurality of front bus bars 401, 402, 403, 404, 405. As shown in FIGS. 9 and 10, the solar cell 400 can be divided into five solar cell strips, with the first solar cell strip being the front busbar from left to right in the order shown in FIGS. 9 and 10. The strip of the second solar cell has the front bus bar 402 and the rear bus bar 407, the strip of the third solar cell has the front bus bar 403 and the rear bus bar 408, and the strip of the fourth solar cell has 401 and the rear bus bar 406. The strip comprises a front bus bar 404 and a rear bus bar 409, and the strip of the fifth solar cell comprises a front bus bar 405 and a rear bus bar 410. As described above, each of the strips of the first to fifth solar cells is provided with a front bus bar on one long edge and a rear bus bar on the other long edge, and the first one. ~ At least one solar cell strip in the fifth solar cell strip has a front busbar on one long edge and a short edge that intersects it, in other words, the long edge has a busbar and the intersecting short edges It has an extension of the busbar.

Specifically, the two outermost solar cell strips in the first to fifth solar cell strips, that is, the first solar cell strip and the fifth solar cell strip, are chamfered. The strip of the first solar cell is also the chamfer section 431 on the left side, and the strip of the fifth solar cell is also the chamfer section 435 on the right side. The front busbar 401 in the left chamfered section 431 with chamfers extends along the long side on one side without chamfers and after reaching the short side intersecting the long side (the embodiment in the figure is vertical). The front bus bar 401 subsequently extends along the short side, i.e. comprises an extension portion 411 of the bus bar. The extension portion 411 extends to the chamfer 421 along the intersecting short edges 431-1 of the chamfer section 431. The extension portion 411 may extend all the way to chamfer 421, or may extend along a portion of the intersecting short edge 431-1 area of the chamfer section 431 and not extend to chamfer 421. The extension portion 411 may be a straight line and the width does not gradually change, that is, may have a constant width, or may be a straight line and the width may gradually change, that is, may have a changing width.

By designing an extension of the front busbar near the edge or chamfer of the solar cell, it is possible to increase the current collection capacity of the solar battery and improve the power of the boarding module.

Similarly, the strip of the fifth solar cell, the front busbar 405 in the right chamfered section 435, extends along the long side on one side without chamfers to the short side that intersects the long side, and then the front busbar. 405 subsequently extends along the short side, i.e. comprises an extension of the busbar. The extension extends to the chamfer 422 along the short edge of the right chamfer section 435, and the extension may extend all the way to the chamfer 422, or is part of the short edge area of the other chamfer section 435. It does not have to extend along the chamfer 422.

Of course, in the embodiments shown in the figure, the extension of the busbar is located on the lower short edge that intersects the long side of the strip of the solar cell, and one of ordinary skill in the art will eventually be on one short edge or above and below. It can be understood that the extension of the busbar may be installed on the two intersecting short edges.

11 and 12 show the front surface of the solar cell and the back surface of the solar cell of the solar cell 500 of one preferred embodiment according to the present invention by top view and bottom view, respectively. The solar cell 500 shown in the figure consists of a slice of a square bar with four ridges chamfered, so when viewed from the front of the solar cell and the back of the solar cell, the solar cell is almost square with chamfers at the four corners. Is. That is, the solar cell 500 includes chamfers 521, 522, 523, and 524.

A plurality of parallel front bus bars 501, 502, 503, 504, and 505 parallel to two edges in the solar cell are arranged on the front surface of the solar cell, and a solar cell is arranged on the back surface of the solar cell. A plurality of parallel rear busbars 506, 507, 508, 509, 510 parallel to each other parallel to the same two edges inside are arranged. Since the arrangement of the plurality of front bus bars and the plurality of rear bus bars is the same as that of the embodiments shown in FIGS. 7 and 8, duplicate description will be omitted.

The front bus bar 501 in the left chamfered section 531 with chamfers extends along the long side of one side without chamfers to the short side intersecting the long side, followed by the front bus bar 501 along the short side. It is extended, that is, includes an extension portion 511 of the bus bar. The extension portion 511 extends along the entire area of the intersecting short edges 531-1 of the chamfered section 531 and subsequently extends along the chamfered edge 531-2 of the chamfered section 531. May extend along the entire area of the chamfered edge 531-2, or may extend along only part of the area of the chamfered edge 531-2. The extension portion 511 may be a straight line and the width does not gradually change, that is, may have a constant width, or may be a straight line and the width may gradually change, that is, may have a changing width.

Similarly, the strip of the fifth solar cell, the front busbar 505 in the right chamfered section 523, extends along the long side on one side without chamfers to the short side that intersects the long side, and then the front busbar. 505 subsequently extends along the short side, i.e. comprises an extension of the busbar. The extension may extend along the short edge of the other chamfered section 523, the extension may extend all the way to chamfer 522, or a portion of the short edge area of the other chamfered section 523. It does not have to extend along the chamfer 522. Further, the extension of the bus bar 505 preferably extends along the entire short edge of the other chamfered section 523, followed by a portion or the entire area of the chamfered edge of the other chamfered section 523.

Of course, in the embodiments shown in the figure, the extension of the busbar is located on the lower short edge that intersects the long side of the strip of the solar cell, and one of ordinary skill in the art will eventually be on one short edge or above and below. It can be understood that the extension of the busbar may be installed on the two intersecting short edges.

13 and 14 show the front surface of the solar cell and the back surface of the solar cell of the solar cell 600 of one preferred embodiment according to the present invention by top view and bottom view, respectively. The solar cell 600 shown in the figure consists of a slice of a square bar with four ridges chamfered, so when viewed from the front of the solar cell and the back of the solar cell, the solar cell is almost square with chamfers at the four corners. Is. That is, the solar cell 600 includes chamfers 621, 622, 623, and 624.

A plurality of parallel front bus bars 601, 602, 603, 604, and 605 parallel to two edges in the solar cell are arranged on the front surface of the solar cell, and a solar cell is arranged on the back surface of the solar cell. A plurality of parallel rear busbars 606, 607, 608, 609, 610 parallel to the same two edges inside are arranged. The solar cell comprises a plurality of juxtaposed sections 631, 632, 633, 634, 635, each section comprising one front busbar and one rear busbar, respectively.

In this embodiment, the plurality of front bus bars 601, 602, 603, 604, 605 are arranged in front of the solar cell at uneven intervals. The plurality of front bus bars 601, 602, 603, 604, 605 include two adjacent front bus bars 604, 605, and the two adjacent front bus bars 604, 605 are the solar cells with respect to the other front bus bars. Close to the edge of. In this embodiment, the two adjacent front busbars 604, 605 are located in the section closest to the edge.

After the solar cell 600 is split into strips of solar cells in the section, each strip of solar cell has a front busbar on one long edge and a back busbar on the other long edge, and at least one. The arrangement of the plurality of rear busbars 606, 607, 608, 609, 610 is such that the strips of one solar cell have front busbars on one long edge and short edges intersecting the front busbars 601. Corresponds to the arrangement of 602, 603, 604, 605. As shown in FIGS. 13 and 14, the solar cell 600 can be divided into five solar cell strips, with the first solar cell strip being the front busbar from left to right in the order shown in FIGS. 13 and 14. The strip of the second solar cell has the front bus bar 602 and the rear bus bar 607, the strip of the third solar cell has the front bus bar 603 and the rear bus bar 608, and the strip of the fourth solar cell has 601 and the rear bus bar 606. The strip comprises a front bus bar 604 and a rear bus bar 609, and the strip of the fifth solar cell comprises a front bus bar 605 and a rear bus bar 610. As described above, each of the strips of the first to fifth solar cells has a front bus bar on one long edge and a rear bus bar on the other long edge, and the first one. ~ At least one solar cell strip in the fifth solar cell strip has a front busbar on one long edge and a short edge that intersects it, in other words, the long edge has a busbar and the intersecting short edges It has an extension of the busbar.

Specifically, the two outermost solar cell strips in the first to fifth solar cell strips, that is, the first solar cell strip and the fifth solar cell strip, are chamfered. The strip of the first solar cell is also the chamfer section 631 on the left side, and the strip of the fifth solar cell is also the chamfer section 635 on the right side. The front busbar 601 in the left chamfered section 631 with chamfers extends along the long side on one side without chamfers and after reaching the short side intersecting the long side (the embodiment in the figure is vertical). The front busbar 601 subsequently extends along the short side, i.e. comprises an extension portion 611 of the busbar. As shown in the figure, the extension portion 611 extends along the short edge 631-1 of the chamfered section 631. The extension portion 611 may extend all the way to chamfer 621 or may extend along a portion of the area of the short edge 631-1 and not extend to chamfer 621. The extension portion 611 may be a straight line and the width does not gradually change, that is, may have a constant width, or may be a straight line and the width may gradually change, that is, may have a changing width.

By designing an extension of the front busbar near the intersecting short sides or chamfers of the solar cell, it is possible to increase the current collection capacity of the solar battery and improve the power of the boarding module.

Similarly, the strip of the fifth solar cell, the front busbar 605 in the right chamfered section 635, extends along the long side on one side without chamfers and intersects the long side (the embodiment in the figure is vertical). After reaching the short side (there is), the front busbar 605 subsequently extends along the short side, i.e. comprises an extension of the busbar. The extension extends along the short edge of the right chamfer section 635, and the extension may extend all the way to chamfer 622, or extend along only part of the short edge area to chamfer 622. It does not have to extend.

Of course, in the embodiments shown in the figure, the extension of the busbar is located on the lower short edge that intersects the long side of the strip of the solar cell, and one of ordinary skill in the art will eventually be on one short edge or above and below. It can be understood that the extension of the busbar may be installed on the two intersecting short edges.

15 and 16 show the front surface of the solar cell and the back surface of the solar cell of another preferred embodiment of the solar cell 700 according to the present invention by top and bottom views, respectively. The solar cell 700 shown in the figure consists of a slice of a square bar with four ridges chamfered, so when viewed from the front of the solar cell and the back of the solar cell, the solar cell is almost square with chamfers at the four corners. Is. That is, the solar cell 700 includes chamfers 721, 722, 723, and 724.

A plurality of parallel front bus bars 701, 702, 703, 704, and 705 parallel to two edges in the solar cell are arranged on the front surface of the solar cell, and a solar cell is arranged on the back surface of the solar cell. A plurality of parallel rear busbars 706, 707, 708, 709, 710 parallel to the same two edges inside are arranged. The solar cell comprises a plurality of juxtaposed sections 731, 732, 733, 734, 735, each section comprising one front busbar and one rear busbar, respectively.

In the embodiments shown in FIGS. 15 and 16, the arrangement of the plurality of front busbars and the plurality of rear busbars is the same as that of the embodiments shown in FIGS. 13 and 14, so duplicate description will be omitted.

The front busbar 701 in the left chamfered section 731 with chamfers extends along the long side on one side without chamfers and crosses the long side (in the figure, the embodiment is vertical) after reaching the short side. The front bus bar 701 subsequently extends along the short side, i.e. comprises an extension portion 711. In the present embodiment, the extension portion 711 extends along the entire area of the short edge 731-1 of the chamfered section 731, and subsequently extends along the chamfered edge 731-2 of the chamfered section 731. The extension portion 711 may extend along the entire area of the chamfered edge 731-2, or may extend along a portion of the area of the chamfered edge 731-2. The extension portion 711 may be a straight line and the width does not gradually change, that is, may have a constant width, or may be a straight line and the width may gradually change, that is, may have a changing width.

On the other side of the solar cell, the busbar 705 in the other chamfered section 735 with a chamfer may be provided with an extension extending along the short edge of the other chamfered section 735, the extension extending all the way to the chamfer 722. It may extend or may extend along only part of the area of the right-angled short edge of the other chamfer section 735 and not extend to the chamfer 722. Further, the front busbar 705 extension preferably extends along the entire short edge of the other chamfered section 735, followed by a portion or the entire area of the chamfered edge of the other chamfered section 735. ..

17 and 18 show the front surface of the solar cell and the back surface of the solar cell of the solar cell 800 of one preferred embodiment according to the present invention by top view and bottom view, respectively. The solar cell 800 shown in the figure consists of a slice of a square bar with four ridges chamfered, so when viewed from the front of the solar cell and the back of the solar cell, the solar cell is almost square with chamfers at the four corners. Is. That is, the solar cell 800 includes chamfers 821, 822, 823, and 824.

A plurality of parallel front bus bars 801, 802, 803, 804, 805 parallel to two edges in the solar cell are arranged on the front surface of the solar cell, and a solar cell is arranged on the back surface of the solar cell. A plurality of parallel rear bus bars 806, 807, 808, 809, 810 parallel to the same two edges inside are arranged. The solar cell comprises a plurality of juxtaposed sections 831, 832, 833, 834, 835, each containing one front busbar and one rear busbar, respectively.

In this embodiment, the plurality of front bus bars 801, 802, 803, 804, 805 are arranged in front of the solar cell at uneven intervals. The plurality of front bus bars 801, 802, 803, 804, 805 include two pairs of front bus bars 802, 803 and 804, 805, and two front bus bars of each of the two pairs of front bus bars are adjacent to each other. Of the pair of front busbars, the pair of front busbars 804, 805 are close to one edge of the solar cell, and the other pair of front bus bars 802, 803 are not close to any edge of the solar cell.

After the solar cell 800 is split into strips of a plurality of solar cells in the section, each solar cell strip has a front busbar on one long edge and a back busbar on the other long edge, at least. The arrangement of the plurality of rear busbars 806, 807, 808, 809, 810 is such that the strips of one solar cell have front busbars on one long edge and short edges intersecting the front busbars 801. , 802, 803, 804, 805. As shown in FIGS. 17 and 18, the solar cell 800 can be divided into five solar cell strips, with the first solar cell strip being the front busbar in the order shown in FIGS. 17 and 18 from left to right. The strip of the second solar cell has the front bus bar 802 and the rear bus bar 807, the strip of the third solar cell has the front bus bar 803 and the rear bus bar 808, and the strip of the fourth solar cell has 801 and the rear bus bar 806. The strip comprises a front bus bar 804 and a rear bus bar 809, and the strip of the fifth solar cell comprises a front bus bar 805 and a rear bus bar 810. As described above, each of the strips of the first to fifth solar cells has a front bus bar on one long edge and a rear bus bar on the other long edge, and the first one. ~ At least one solar cell strip in the fifth solar cell strip has a front busbar on one long edge and a short edge that intersects it, in other words, the long edge has a busbar and the intersecting short edges It has an extension of the busbar.

Specifically, the two outermost solar cell strips in the first to fifth solar cell strips, that is, the first solar cell strip and the fifth solar cell strip, are chamfered. The strip of the first solar cell is also the chamfered section 831 on the left side, and the strip of the fifth solar cell is also the chamfered section 835 on the right side. The front busbar 801 in the left chamfered section 831 with chamfers extends along the long side on one side without chamfers and crosses the long side (in the figure, the embodiment is vertical) after reaching the short side. The front bus bar 801 subsequently extends along the short side, i.e. comprises an extension portion 811. The extension portion 811 extends to the chamfer 821 along the intersecting short edges 831-1 of the chamfer section 831. The extension portion 811 may extend all the way to chamfer 821, or may extend along only part of the area of the intersecting short edges 831-1 of the chamfer section 831 and not extend to chamfer 821. The extension portion 811 may be a straight line and the width does not gradually change, that is, may have a constant width, or may be a straight line and the width may gradually change, that is, may have a changing width.

By designing an extended front busbar near the intersecting short sides or chamfers of the solar cell, it is possible to increase the current collection capacity of the solar battery and improve the power of the boarding module.

Similarly, the strip of the fifth solar cell, the front busbar 805 in the right chamfered section 835, extends along the long side on one side without chamfers and intersects the long side (the embodiment in the figure is vertical). After reaching the short side (there is), the front busbar 805 subsequently extends along the short side, i.e. comprises an extension. The extension extends to chamfer 822 along the short edge of the right chamfer section 835, and the extension may extend all the way to chamfer 822, or is part of the area of the short edge of the other chamfer section 835. It does not have to extend along the chamfer 822.

Of course, in the embodiments shown in the figure, the extension of the busbar is located on the lower short edge that intersects the long side of the strip of the solar cell, and one of ordinary skill in the art will eventually be on one short edge or above and below. It can be understood that the extension of the busbar may be installed on the two intersecting short edges.

19 and 20 show the front surface of the solar cell and the back surface of the solar cell of the solar cell 900 of one preferred embodiment according to the present invention by top view and bottom view, respectively. The solar cell 900 shown in the figure consists of slices of square bars with four ridges chamfered, so when viewed from the front of the solar cell and the back of the solar cell, the solar cell is almost square with chamfers at the four corners. Is. That is, the solar cell 900 includes chamfers 921, 922, 923, and 924.

A plurality of parallel front bus bars 901, 902, 903, 904, 905 parallel to two edges in the solar cell are arranged on the front surface of the solar cell, and a solar cell is arranged on the back surface of the solar cell. A plurality of parallel rear busbars 906, 907, 908, 909, 910 parallel to the same two edges inside are arranged. Since the arrangement of the plurality of front bus bars and the plurality of rear bus bars is the same as that of the embodiments shown in FIGS. 17 and 18, duplicate description will be omitted.

The front busbar 901 in the left chamfered section 931 with chamfers extends along the long side on one side without chamfers to the short side intersecting the long side, followed by the front busbar 901 along the short side. It includes an extension, i.e., an extension portion 911. The extension portion 911 extends along the entire area of the intersecting short edges 931-1 of the chamfered section 931 and subsequently extends along the chamfered edge 931-2 of the chamfered section 931. May extend along the entire area of the chamfered edge 931-2, or may extend along only a portion of the area of the chamfered edge 931-2. The extension portion 911 may be a straight line and the width does not gradually change, that is, may have a constant width, or may be a straight line and the width may gradually change, that is, may have a changing width.

Similarly, the strip of the fifth solar cell, the front busbar 905 in the right chamfered section 923, extends along the long side on one side without chamfers to the short side that intersects the long side, and then the front busbar. 905 subsequently extends along the short side, i.e. provides an extension. The extension may extend along the short edge of the other chamfered section 923, the extension may extend all the way to chamfer 922, or part of the short edge area of the other chamfered section 923. It does not have to extend along the chamfer 922. Further, the extension of the bus bar 905 preferably extends along the entire short edge of the other chamfered section 923, followed by a portion or the entire area of the chamfered edge of the other chamfered section 923.

FIG. 21 is a flow chart showing a method of manufacturing a solar cell for a plate-roofing module according to the present invention. The method is
A step of arranging a rear bus bar, that is, arranging a plurality of rear bus bars on the back surface of the solar cell,
A plurality of front busbars are arranged in front of the solar cell of the solar cell, the plurality of front busbars divide the solar cell into a plurality of sections, and the front busbars are as shown in FIGS. 3 and 6. Alternatively, they may be arranged as shown in FIGS. 9, 11 or 13, 15, or as shown in FIGS. 17, 19 and at least the solar cell. With the step of disposing the front busbar of one section, eg, a chamfered section with chamfers, having extensions at one end or both ends, the extension extending along the edge of at least one section. ,
After the solar cell is divided into a plurality of strips, the arrangement of the plurality of front busbars corresponds to the arrangement of the plurality of rear busbars so that one side of each strip is the front busbar and the other side is the rear busbar. Including the step.

The extension of the front busbar may extend along a portion or the entire area of the short edge of the chamfered section. Further, it is preferred that the extension extends along the entire short edge area of the chamfered section and subsequently along a portion or the entire area of the chamfered edge of the chamfered section. The extension portion may be a straight line and the width does not gradually change, or a straight line and the width may gradually change.

According to the method of the present invention, it is possible to provide a solar cell, particularly an extension of the bus bar near the intersecting short sides or chamfers, to increase the current collection capacity of the solar battery and improve the power of the boarding module. ..

Those skilled in the art can understand that the above contents describe in detail a preferred embodiment of the idea of the present invention, and according to the present invention, the solar cell front and / or back busbars are uniformly arranged. Each of the strips of the solar cell may have a front busbar on one long edge after the solar cell has been split into strips of the solar cell, which may be arranged non-uniformly. And a back busbar on the long edge on the other side, and a busbar (front and / or back) on the long edge on one side and the short edge where at least one strip of the solar cell in the strip of the solar cell intersects it. In other words, the long edge is provided with a bus bar, and the intersecting short edges are provided with an extension of the bus bar.

The scope of the present invention to be protected is limited only to the claims. It is easy for those skilled in the art to understand that a configuration that replaces the configuration disclosed in the present invention is a feasible alternating embodiment by the guidance of the present invention, and a new embodiment disclosed in the present invention is combined. Embodiments may be formed, or the invention may be applied to other similar areas, which of course fall within the scope of the appended claims.

Claims (18)

A solar cell comprising a positive surface and a back surface, the front KiTadashi surface, a plurality of front bus bar is disposed, before xenon surface, a plurality of back bus bars is disposed,
The solar cell comprises a plurality of sections, each of which is a solar cell for a board-roofed solar cell module, including one front busbar and one rear busbar located at the edge of the section .
Each front busbar has a body, and the body is not located on the edge of the solar cell.
At least one section of the front bus bar of the solar cell comprises an extension at one end or both ends, the extension portion, the other edge of said at least one section intersecting said edge the front bus bar is positioned along extension beauty,
The solar cell comprises chamfering, and an extension of the front busbar of at least one chamfered section of the solar cell extends along the other edge of the chamfered section that intersects the edge of the section where the front busbar is located. ,
The extension extends along the entire area of the other edge of the chamfered section and continues to extend along a portion or the entire area of the other edge of the chamfered section adjacent to the other edge. ,
Solar cell for the Itabuki solar module. The extension portion is a straight line and the width does not gradually change , or is a straight line and the width gradually changes.
Seo Raseru of claim 1, wherein the. Wherein the plurality of front bus bar is arranged in front KiTadashi surface evenly spaced,
Seo Raseru of claim 1, wherein the. Wherein the plurality of front bus bar is arranged in front KiTadashi surface at unequally intervals,
Seo Raseru of claim 1, wherein the. Wherein the plurality of front bus bar includes two front bus bar fit Ri next, the two positive surfaces bus bars, not close to the edge of the solar cell to the other front bus bar,
Seo Raseru of claim 4, characterized in that. The plurality of front bus bars include two pairs of front bus bars, two pairs of front bus bars of each pair of the two pairs of front bus bars are adjacent to each other, and the two pairs of front bus bars are each one edge of the solar cell. Close to,
Seo Raseru of claim 4, characterized in that. Wherein the plurality of front bus bar includes two front bus bar fit Ri next, the two positive surfaces bus bar, close to the edge of the solar cell,
Seo Raseru of claim 4, characterized in that. The plurality of front bus bars include two pairs of front bus bars, two pairs of front bus bars of each pair of the two pairs of front bus bars are adjacent to each other, and a pair of front bus bars of the two pairs of front bus bars is the solar. close to the edge of the cell, the front bus bar of the other side of the pair of front bus bar of the two pairs are not close to the edge of the solar cell,
Seo Raseru of claim 4, characterized in that. After the solar cell is split into strips of multiple solar cells, the front busbar is adjacent to the long edge on one side of the corresponding solar cell strip and the short edge adjacent to it , and the rear busbar is adjacent to the long edge on the other side. The arrangement of the plurality of rear busbars corresponds to the arrangement of the plurality of front busbars so as to fit .
Seo Raseru of claim 3, characterized in that. Produced by the pre-Symbol claims 1-9 any one solar cell strips divided from the solar cell according to Section,
Characterized in that, Itabuki solar cell module. Itabuki A method of making a solar cell for solar cell modules,
The method is
Arranged a plurality of bus bars and the positive side towards the rear, the plurality of bus bars divides the solar cell into a plurality of sections, each section, and one of the front bus bar and a rear bus bar, located at the edge of the section hints, each front bus bar includes a body, the body to the edge of the solar cell is not located, the front bus bar of the at least one section of the solar cell comprises an extension at one end or both ends, the extension but the front bus bar extending along the other edge of said at least one section intersecting said edge located, viewed including the,
The solar cell comprises a chamfer, and an extension of the front busbar of at least one chamfered section of the solar cell with the chamfer extends along the other edge of the chamfered section that intersects the edge on which the front busbar is located.
The extension extends along the entire area of the other edge of the chamfered section and continues to extend along a portion or the entire area of the other edge of the chamfered section adjacent to the other edge. ,
The method described above . The extension portion is a straight line and the width does not gradually change , or is a straight line and the width gradually changes.
Method person according to claim 11, characterized in that. Wherein the plurality of front bus bar is arranged in front KiTadashi surface evenly spaced,
Method person according to claim 11, characterized in that. Wherein the plurality of front bus bar is arranged in front KiTadashi surface at unequally intervals,
Method person according to claim 11, characterized in that. Wherein the plurality of front bus bar includes two front bus bar fit Ri next, the two positive surfaces bus bars, not close to the edge of the solar cell to the other front bus bar,
Method person according to claim 14, characterized in that. The plurality of front bus bars include two pairs of front bus bars, two pairs of front bus bars of each pair of the two pairs of front bus bars are adjacent to each other, and the two pairs of front bus bars are each one edge of the solar cell. Close to,
Method person according to claim 14, characterized in that. Wherein the plurality of front bus bar includes two front bus bar fit Ri next, the two positive surfaces bus bar, close to the edge of the solar cell,
Method person according to claim 14, characterized in that. The plurality of front bus bars include two pairs of front bus bars, two pairs of front bus bars of each pair of the two pairs of front bus bars are adjacent to each other, and a pair of front bus bars of the two pairs of front bus bars is the solar. close to the edge of the cell, the front bus bar of the other side of the pair of front bus bar of the two pairs are not close to the edge of the solar cell,
Method person according to claim 14, characterized in that.